A sensitivity study of the key parameters in the interfacial photopolymerization of poly(ethylene glycol) diacrylate upon porcine islets

A method has been defined to interfacially photopolymerize poly(ethylene glycol) diacrylates (PEG diacrylates) to form a crosslinked hydrogel membrane upon the surfaces of porcine islets of Langerhans to serve as an immune barrier for allo- and xenotransplantation. A sensitivity study of six key parameters in the interfacial photopolymerization process was performed to aid in determination of the optimal encapsulation conditions, leading to the most uniform hydrogel membranes and viable islets. The key parameters included the concentrations of the components of the initiation scheme, namely eosin Y, triethanolamine, and 1-vinyl 2-pyrrolidinone. Other parameters investigated included the duration and flux of laser irradiation and the PEG diacrylate molecular weight. Each parameter was doubled and halved from the standard conditions used in the encapsulation process while holding all the remaining parameters at the standard conditions. The effects of changing each parameter on islet viability, encapsulation efficiency, and gel thickness were quantified. Islet viability was sensitive to the duration of laser illumination, viability significantly increasing as the duration was reduced. Encapsulation efficiency was sensitive to the concentrations of eosin Y, triethanolamine, and 1-vinyl 2-pyrrolidinone, to the laser flux, and to the PEG diacrylate molecular weight. Increasing the concentration of eosin Y significantly improved the encapsulation efficiency, while decreasing the concentration of 1-vinyl 2-pyrrolidinone and increasing the concentration of triethanolamine had the greatest effects in significantly reducing the encapsulation efficiency. Gel thickness was sensitive to the concentrations of triethanolamine and 1-vinyl 2-pyrrolidinone, to the duration of laser illumination, and to the PEG diacrylate molecular weight. Increasing the PEG diacrylate molecular weight significantly increased the gel thickness, while decreasing the concentration of 1-vinyl 2-pyrrolidinone and increasing the concentration of triethanolamine had the greatest effects in significantly reducing the gel thickness. From this sensitivity study, conditions were determined to encapsulate porcine islets, resulting in greater than 90% islet viability and greater than 90% encapsulation efficiency.     

Prevention of complement-mediated cytotoxicity against rat islets by encapsulation in a cellulose sulphate membrane

The immuno-isolation by semipermeable membranes should prevent the immunological destruction of the transplanted tissue. The polyelectrolyte complex membrane from cellulose sulphate and poly(dimethyldiallylammoniumchloride), which does not alter the viability of the encapsulated rat islets, can prevent complement-mediated cytotoxicity. The 51Cr release from prelabelled islets, which was induced by either unspecific cytotoxicity of rabbit sera against the rat islets or by an anti-MHC rat serum in presence of complement, was prevented. The diffusion of immunoglobulins as well as of factors of the complement system was inhibited by encapsulation. The capsule membrane also prevents the beta-cell destruction in cytotoxic sera from newly diagnosed type-I diabetics measured as insulin leakage after blocking the active hormone secretion. In conclusion, the cellulose sulphate membrane seems to be useful for the transplantation of encapsulated islets.     

Thermally induced gelable polymer networks for living cell encapsulation

We report the encapsulation of MIN6 cells, a pancreatic beta-cell line, using thermally induced gelable materials. This strategy uses aqueous solvent and mild temperatures during encapsulation, thereby minimizing adverse effects on cell function and viability. Using a 2:1 mixture of PNIPAAm-PEG-PNIPAAm tri-block copolymer and PNIPAAm homopolymer that exhibit reversible sol-to-gel transition at approximately 30 degrees C, gels were formed that exhibit mechanical integrity, and are stable in H(2)O, PBS and complete DMEM with negligible mass loss at 37 degrees C for 60 days. MTT assays showed undetectable cytotoxicity of the polymers towards MIN6 cells. A simple microencapsulation process was developed using vertical co-extrusion and a 37 degrees C capsule collection bath containing a paraffin layer above DMEM. Spherical capsules with diameters ranging from 500 to 900 microm were formed. SEM images of freeze-dried capsules with PBS as the core solution showed homogenous gel capsule membranes. Confocal microscopy revealed that the encapsulated cells tended to form small aggregates over 5 days, and staining for live and dead cells showed high viability post-encapsulation. A static glucose challenge with day-5 cultured microencapsulated cells exhibited glucose-dependent insulin secretion comparable to controls of free MIN6 cells grown in monolayers. These results demonstrate the potential use of these thermo-responsive polymers as cell encapsulation membranes.     

Eosin Y-sensitive ATPase activity in men's spermatozoids as a biochemical test for oligozoospermia

The experiments performed on preparations of spermatozoids of men of reproductive age (27-44-year old) studied the ATPase activity (sensitive to inhibited effects of eosine Y) in both normal and oligozoospermia conditions when treating cell suspension with detergents. The methodical approaches for testing the so-called "common" and eosin Y-sensitive ATP-hydrolase activities in spermatozoids were developed. Saponin, the optimal detergent for permeabilisation of their plasma membrane was chosen using laser-correlational spectroscopia method. Saponin perforates effectively the membranes of spermatozoids, decreasing the average hydrodynamical diameter of cells from 10-15 microm (the spermatozoids themselves) to 3-8 microm (treating cell suspension with 0.05% solution of saponin) and even to 2-3 microm (treating spermatozoids suspension with 0.5% solution of detergent). A non-specific inhibitor of ATP-hydrolase's systems, eosin Y, decreases effectively the ATP-hydrolase activity of intact spermatozoids up to 40%. The exact effect of eosin depends on composition of incubation medium. In the model of extracellular conditions (the optimal concentration of detergent is 0.05%), eosin Y-sensitive ATP-hydrolase's activity of spermatozoids in both normal and oligozoospermia cases is increased by 220-240% (at an average). If enzymatic reaction was performed during intracellular conditions modeling (the optimal concentration of saponin is 0.5%), the increase of eosin Y-sensitive ATPase activity (up to 350-400% in normal conditions, and only to 130-150% in oligozoospermia conditions) was detected. This specificity can be used as easy-to-use clinical test for such pathology of men's reproductive system. Eosin Y inhibited doze-dependently the common ATPase activity in spermatozoids in both normal and with studied pathology. In both cases, after linearization of curves of catalytic titration of ATPase activity with eosin Y in Hill's plot the two-phase dependency, of high and low affinities, was found (the average values of imaginary inhibition constant I(0,5) are 0.1 and 0.3-0.4 mM correspondingly). In both normal and oligozoospermia conditions, the high-affinity component has a positive cooperativity, while the low-affinity component is characterized by a negative cooperativity. The obtained results may be of both theoretical and practical value for further investigation of membrane mechanisms used in the support of ion homeostasis in men's spermatozoids and its violation in conditions under different pathological states. Besides, the results can be used as a theoretical basis for improvement of simple and accessible clinical biochemical methods used for testing such a pathology as oligozoospermia.     

An improved method of microencapsulation and its evaluation to protect Lactobacillus spp. in simulated gastric conditions

An improved method of microencapsulation was developed to increase the efficacy of capsules in protecting the encapsulated bacteria under simulated gastric conditions. Lactobacillus acidophilus CSCC 2400 was encapsulated in calcium alginate and tested for its survival in simulated gastric conditions. The effects of different capsule sizes (200, 450, 1000 microm), different sodium alginate concentrations (0.75%, 1%, 1.5%, 1.8% and 2% w/v) and different concentrations of calcium chloride (0.1, 0.2, 1.0 M) on the viability of encapsulated bacteria were investigated. The viability of the cells in the microcapsules increased with an increase in alginate capsule size and gel concentration. There was no significant difference (p>0.05) in the viability of encapsulated cells when the concentration of calcium chloride was increased. Increase in cell load during encapsulation increased the number of bacterial survivors at the end of 3-h incubation in simulated gastric conditions. Hardening the capsule in calcium chloride solution for a longer time (8 h) had no impact on increasing the viability of encapsulated bacteria in a simulated gastric environment. The release of encapsulated cells at different phosphate buffer concentrations was also studied. When encapsulated L. acidophilus CSCC 2400 and L. acidophilus CSCC 2409 were subjected to low pH (pH 2) and high bile concentration (1.0% bile) under optimal encapsulation conditions (1.8% (w/v) alginate, 10(9) CFU/ml, 30 min hardening in 0.1 M CaCl(2) and capsule size 450 microm), there was a significant increase (p<0.05) in viable cell counts, compared to the free cells under similar conditions. Thus the encapsulation method described in this study may be effectively used to protect the lactobacillus from adverse gastric conditions.     

Permeability of alginate microcapsules to secretory recombinant gene products

Non-autologous somatic gene therapy is an alternate approach to delivering recombinant gene products through implantation of a "universal" donor cell line engineered to produce a therapeutic gene product. The cells are immunologically isolated by enclosure in immunoprotective microcapsules fabricated from alginate-poly-L-lysine-alginate. The molecular weight cutoff of these microcapsules was thought to be <100 kd, thus, excluding the immunoglobulins. However, when such microcapsules are fabricated to enclose cells, they show a higher permeability threshold than expected. The secretion rates of recombinant gene products ranging from 21 through 150 to 300 kd (human growth hormone, rat serum albumin, human arylsulfatase A, human immunoglobulin, mouse beta-hexosaminidase, mouse beta-glucuronidase) were similar between the nonencapsulated and encapsulated recombinant cells with the exception of the largest molecular species, the 300-kd beta-glucuronidase. Its secretion was reduced about eightfold after encapsulation. Increasing the thickness of the membrane by prolonging the coating time with poly-L-lysine did not provide a lower molecular weight cutoff. An additional coating with alginate, however, reduced the leakage of the larger molecular species, but the effect was short lived: After 2 weeks in culture, the double- and single-coated microcapsules were equally permeable. Both the increased poly-L-lysine and alginate coating were detrimental to the long-term viability and proliferation of the encapsulated cells. Hence, immunoisolation of encapsulated cells with alginate-poly-L-lysine-alginate microcapsules cannot provide a molecular weight cutoff below 300 kd. (c) 1996 John Wiley & Sons, Inc.     

Effect of eosin Y on Ca2+, Mg2+-ATPase of the smooth muscle sarcolemma

Eosin Y was studied with the aim to elucidate the mechanism of its inhibitory effect on the activity of Ca(2+)-transporting ATPase of myometrium cell plasma membrane. The inhibitor was studied for its effect on the maximal rate of the ATP-hydrolase reaction catalyzed by Ca2+, Mg(2+)-ATPase, on the enzyme affinity for the substrate and a possibility of enzyme activity protection under the inhibitor effect by the main reagents of ATP-hydrolase reaction. It was established that eosin Y decreased the turnover rate of this enzyme and his affinity for ATP. Preincubation of ATPase with ATP (or ATP plus MgCl2) had no effect on the extent of enzyme inhibition by eosin Y. This result proves that eosin Y and ATP do not compete for the site of binding on the enzyme.     

A molecular docking strategy identifies Eosin B as a non-active site inhibitor of protozoal bifunctional thymidylate synthase-dihydrofolate reductase

Protozoal parasites are unusual in that their thymidylate synthase (TS) and dihydrofolate reductase (DHFR) enzymes exist on a single polypeptide. In an effort to probe the possibility of substrate channeling between the TS and DHFR active sites and to identify inhibitors specific for bifunctional TS-DHFR, we used molecular docking to screen for inhibitors targeting the shallow groove connecting the two active sites. Eosin B is a 100 microm non-active site inhibitor of Leishmania major TS-DHFR identified by molecular docking. Eosin B slows both the TS and DHFR reaction rates. When Arg-283, a key residue to which eosin B is predicted to bind, is mutated to glutamate, however, eosin B only minimally inhibits the TS-DHFR reaction. Additionally, eosin B was found to be a 180 microm inhibitor of Toxoplasma gondii in both biochemical and cell culture assays.     

Adhesion study of silicone coatings: the interaction of thickness, modulus and shear rate on adhesion force

Interactions between coating thickness, modulus and shear rate on pseudobarnacle adhesion to a platinum-cured silicone coating were studied using a statistical experimental design. A combined design method was used for two mixture components and two process variables. The two mixture components, vinyl end-terminated polydimethylsiloxanes (V21: MW=6 kg mole(-1) and V35: MW=4 9.5 kg mole(-1), Gelest Inc.) were mixed at five different levels to vary the modulus. The dry coating thickness was varied from 160 - 740 microm and shear tests were performed at four different shear rates (2, 7, 12, and 22 microm s(-1)). The results of the statistical analysis showed that the mixture components were significant factors on shear stress, showing an interaction with the process variable. For the soft silicone coating based on the high molecular weight polydimethylsiloxane (E=0.08 MPa), shear stress significantly increased as coating thickness decreased, while shear rate slightly impacted shear force especially at 160 microm coating thickness. As the modulus was increased (E=1.3 MPa), more force was required to detach the pseudobarnacle from the coatings, but thickness and rate dependence on shear stress became less important.     

Cell-cycle dependence of heat-induced interphase death in mouse L5178Y cells.

Cell lysis and eosin staining were observed in L5178Y cells within the first 3 h of post-hyperthermia incubation at 37 degrees C, after which both leveled to a plateau. Lysis and eosin staining were proportional to the severity of heat in asynchronous cells, whereas it was maximum in the most heat-sensitive M phase, intermediate in S, and least in heat-resistant G1 for the same heat treatment. Further, leakage of labeled [3H]thymidine and a decrease in radioactivity retained within heated cells coincided with an increase in eosin staining, indicating that the dye uptake was due to membrane damage. It was presumed that the eosin-stained fraction represented dead cells. The percentage eosin-stained cells reached a plateau, and this level was used to determine survival; when the results were compared with those obtained by the colony formation method, they were identical. By comparing the two survival assay methods we concluded that cell death after hyperthermia in L5178Y cells is mainly by interphase death in all phases of the cell cycle. The reasons for this conclusion are that a reduction in survival could be detected within one generation of L5178Y cells by the eosin staining method, and the survival values obtained by this method were identical to those obtained by the colony formation method.     

Hydrogel-perfluorocarbon composite scaffold promotes oxygen transport to immobilized cells

Cell encapsulation provides cells a three-dimensional structure to mimic physiological conditions and improve cell signaling, proliferation, and tissue organization as compared to monolayer culture. Encapsulation devices often encounter poor mass transport, especially for oxygen, where critical dissolved levels must be met to ensure both cell survival and functionality. To enhance oxygen transport, we utilized perfluorocarbon (PFC) oxygen vectors, specifically perfluorooctyl bromide (PFOB) immobilized in an alginate matrix. Metabolic activity of HepG2 liver cells encapsulated in 1% alginate/10% PFOB composite system was 47-104% higher than alginate systems lacking PFOB. A cubic model was developed to understand the oxygen transport mechanism in the alginate/PFOB composite system. The theoretical flux enhancement in alginate systems containing 10% PFOB was 18% higher than in alginate-only systems. Oxygen uptake rates (OURs) of HepG2 cells were enhanced with 10% PFOB addition under both 20% and 5% O2 boundary conditions, by 8% and 15%, respectively. Model predictions were qualitatively and quantitatively verified with direct experimental OUR measurements using both a perfusion reactor and oxygen sensing plate, demonstrating a greater OUR enhancement under physiological O2 boundary conditions (i.e., 5% O2). Inclusion of PFCs in an encapsulation matrix is a useful strategy for overcoming oxygen limitations and ensuring cell viability and functionality both for large devices (>1 mm) and over extended time periods. Although our results specifically indicate positive enhancements in metabolic activity using the model HepG2 liver system encapsulated in alginate, PFCs could be useful for improving/stabilizing oxygen supply in a wide range of cell types and hydrogels.     

Influence of encapsulation on the survival of probiotics in food matrix under simulated stress conditions

The main objective of the present study was to evaluate the influence of encapsulation by extrusion technique using two hydrogels, namely; sodium alginate (Na-ALG) and whey protein isolate (WPI) on Bifidobacterium bifidium viability and stability of yoghurt under simulated gastrointestinal conditions. Probiotic bacteria (free or encapsulated) were added to yogurt for four weeks to test their viability and stability. Physicochemical and sensory analysis of yoghurt were conducted. Viability of B. bifidium in the simulated gastrointestinal conditions pH 2 and pH 7.5 was determined. Also, the efficiency of encapsulated final yield of the microcapsules was determined. With storage time, the pH of yoghurt containing encapsulated bacteria increased more than that of yoghurt containing free probiotic bacteria, resulting in a decrease in acidity. When compared to yoghurt containing encapsulated bacteria, the lactose level of yoghurt containing free probiotic bacteria decreased over time. The viscosity of yoghurt containing encapsulated WPI remained stable over the storage period, with syneresis remaining stable. The sensory properties of yoghurt containing free probiotics deteriorated over time. Cell viability was significantly reduced in yoghurt-containing free probiotics compared to other treated yoghurts. Cell viability in free probiotics yoghurt was lower than in encapsulated ones when exposed to simulated gastric and intestinal juice. In conclusion, WPI- encapsulated probiotics showed better stability over 28 days of storage in both yoghurt and gastrointestinal conditions, followed by sodium alginate.     

Technology and applications for encapsulated spermatozoa

A technique for microencapsulation of bovine spermatozoa has been developed with minimal spermatozoal injury and thus, a potential use in artificial insemination (AI). Membranes made of the following polymers have proven best: poly-l-lysine, polyarginine, polyvinylamine, and protamine sulfate. Successful encapsulation has been achieved for capsules ranging in size from 0.75 to 1.5 mm, and sperm concentrations from 45 to 180 x 10(6) cells/ml. Successful buffers include Cornell University Extender and egg yolk citrate - glycerol (maximum 10% v/v egg yolk for normal capsular shape). Capsule fragility (ability to rupture under aging and physical stress) was negatively related to membrane thickness which ranges from 1.92 microm to 5.32 microm (controlled by polymer concentration, molecular weight, and exposure time) and positively to concentration of sperm encapsulated. On delivery to the porcine reproductive tract, the capsule constructed of poly-l-lysine membranes ruptured between 12 and 24 hr after insemination. Heterospermic studies have shown that encapsulated sperm are capable of fertilization in vivo, but are at a disadvantage to unencapsulated sperm when AI is at conventional times following detection of estrus.     

In situ control of cell adhesion using photoresponsive culture surface

A photoresponsive culture surface (PRCS) allowing photocontrol of cell adhesion was prepared with a novel polymer material composed of poly(N-isopropylacrylamide) having spiropyran chromophores as side chains. Cell adhesion of the surface was drastically enhanced by the irradiation with ultraviolet (UV) light (wavelength: 365 nm); after subsequent cooling and washing on ice, many cells remained in the irradiated region, whereas most cells were removed from the nonirradiated region. The cell adhesion of the PRCS, which had been enhanced by previous UV irradiation, was reset by the visible light irradiation (wavelength 400-440 nm) and the annealing at 37 degrees C for 2 h. Also it was confirmed that the regional control of cell adhesion was induced several times by repeating the same series of operations. Further, living cell patterning with the 200 microm line width was produced readily by projecting UV light along a micropattern on the PRCS on which the living cells had been seeded uniformly in advance. By using a fluorescent probe that stains living cells only, it was confirmed that the cells maintained sufficient viability even after UV light irradiation followed by cooling and washing.     

Preparation and characterization of novel polymeric microcapsules for live cell encapsulation and therapy

This article describes the preparation and in vitro characterization of novel genipin cross-linked alginate-chitosan (GCAC) microcapsules that have potential for live cell therapy applications. This microcapsule system, consisting of an alginate core with a covalently cross-linked chitosan membrane, was formed via ionotropic gelation between calcium ions and alginate, followed by chitosan coating by polyelectrolyte complexation and covalent cross-linking of chitosan by naturally derived genipin. Results showed that, using this design concept and the three-step procedure, spherical GCAC microcapsules with improved membrane strength, suppressed capsular swelling, and suitable permeability can be prepared. The suitability of this novel membrane formulation for live cell encapsulation was evaluated, using bacterial Lactobacillus plantarum 80 (pCBH1) (LP80) and mammalian HepG2 as model cells. Results showed that capsular integrity and bacterial cell viability were sustained 6 mo postencapsulation, suggesting the feasibility of using this microcapsule formulation for live bacterial cell encapsulation. The metabolic activity of the encapsulated HepG2 was also investigated. Results suggested the potential capacity of this GCAC microcapsule in cell therapy and the control of cell signaling; however, further research is required.     

Release characteristics of reattached barnacles to non-toxic silicone coatings

Release mechanisms of barnacles (Amphibalanus amphitrite or Balanus amphitrite) reattached to platinum-cured silicone coatings were studied as a function of coating thickness (210-770 microm), elastic modulus (0.08-1.3 MPa), and shear rate (2-22 microm s(-1)). It was found that the shear stress of the reattached, live barnacles necessary to remove from the silicone coatings was controlled by the combined term (E/t)(0.5) of the elastic modulus (E) and thickness (t). As the ratio of the elastic modulus to coating thickness decreased, the barnacles were more readily removed from the silicone coatings, showing a similar release behavior to pseudobarnacles (epoxy glue). The barnacle mean shear stress ranged from 0.017 to 0.055 MPa whereas the pseudobarnacle mean shear stress ranged from 0.022 to 0.095 MPa.     

Enhance Stability and in vitro Cell Response to a Bioinspired Coating on Zr Alloy with Increasing Chitosan Content

The aim of the present paper is to characterize bioinspired chitosan (CS) + hydroxyapatite (HA) coatings with various components ratio on a zirconium alloy with titanium.The coatings were characterized by FT-IR,SEM,hydrophilic/hydrophobic balance,adherence,roughness,electrochemical stability and in vitro cell response.Electrochemical tests,including potentiodynamic polarization curves and electrochemical impedance spectroscopy,were performed in normal saline physiological solution.Cell viability of MC3T3-E1 osteoblasts,lactate dehydrogenase,nitric oxide,and Reactive Oxygen Species (ROS) levels,as well as actin cytoskeleton morphology,were evaluated as biological in vitro tests.The results on in vitro cell response indicated good cell membrane integrity and viability for all samples,but an increased cell number,a decreased ROS level and a better cytoskeleton organization were noticed for the sample with a higher CS content.The coating with highest CS concentration indicated the best performance based on the experimental data.The highest hydrophilic character,highest resistance to corrosion and best biocompatibility as well recommend this coating for bioapplications in tissue engineering.     

Encapsulation of rat hepatocyte spheroids for the development of artificial liver

Hepatocyte spheroids and hepatocyte were immobilized in chitosan/alginate capsules formed by the electrostatic interactions between chitosan and alginate. After encapsulation, there was a 10% decrease in the viability of spheroids due to the exposure of the cells to a pH 6 during the encapsulation process. However, the encapsulated hepatocyte spheroids maintained over 50% viability and liver specific functions for 2 weeks while the encapsulated hepatocytes, free hepatocytes and free hepatocyte spheroids showed low viability and liver specific functions. Therefore, encapsulated hepatocyte spheroid might be applied to the development of a bioartificial liver.     

Counteracting effect of eosin and related dyestuffs on the production of respiration-deficient mutants in yeast by 4-nitroquinoline 1-oxide

Production of respiration-deficient (rho^?) mutants under growing conditions in a strain of Saccharomyces chevalieri by 4-nitroquinoline 1-oxide (4NQO), a potent carcinogen, reached 100%. the mutation frequency was considerably reduced when eosin Y was applied in various combinations with 4NQO. The counteracting effect was slight when eosin Y was applied concurrently with 4NQO, but was very strong adn persistent when eosin Y was impregnated into the yeast cells before their exposure to 4NQO. Eosin B, erythrosin B and uranin also showed more or less counteracting effects against 4 NQO in producing the rho^? mutants. Possible mechanisms for the counteracting effects of these dyestuffs against 4NQO are discussed in relation to antimutagenesis and chemotherapeutic interference.     

Painting and printing living bacteria: engineering nanoporous biocatalytic coatings to preserve microbial viability and intensify reactivity

Latex biocatalytic coatings containing approximately 50% by volume of microorganisms stabilize, concentrate and preserve cell viability on surfaces at ambient temperature. Coatings can be formed on a variety of surfaces, delaminated to generate stand-alone membranes or formulated as reactive inks for piezoelectric deposition of viable microbes. As the latex emulsion dries, cell preservation by partial desiccation occurs simultaneously with the formation of pores and adhesion to the substrate. The result is living cells permanently entrapped, surrounded by nanopores generated by partially coalesced polymer particles. Nanoporosity is essential for preserving microbial viability and coating reactivity. Cryo-SEM methods have been developed to visualize hydrated coating microstructure, confocal microscopy and dispersible coating methods have been developed to quantify the activity of the entrapped cells, and FTIR methods are being developed to determine the structure of vitrified biomolecules within and surrounding the cells in dry coatings. Coating microstructure, stability and reactivity are investigated using small patch or strip coatings where bacteria are concentrated 102- to 103-fold in 5-75 microm thick layers with pores formed by carbohydrate porogens. The carbohydrate porogens also function as osmoprotectants and are postulated to preserve microbial viability by formation of glasses inside the microbes during coat drying; however, the molecular mechanism of cell preservation by latex coatings is not known. Emerging applications include coatings for multistep oxidations, photoreactive coatings, stabilization of hyperthermophiles, environmental biosensors, microbial fuel cells, as reaction zones in microfluidic devices, or as very high intensity (>100 g.L-1 coating volume.h-1) industrial or environmental biocatalysts. We anticipate expanded use of nanoporous adhesive coatings for prokaryotic and eukaryotic cell preservation at ambient temperature and the design of highly reactive "living" paints and inks.